Reply to: “Hyperoxemia in postsurgical sepsis/septic shock patients is associated with reduced mortality”

© The Author(s) 2022. Open Access This article is licensed under a Creative Commons Attribution 4.0 International License, which permits use, sharing, adaptation, distribution and reproduction in any medium or format, as long as you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons licence, and indicate if changes were made. The images or other third party material in this article are included in the article’s Creative Commons licence, unless indicated otherwise in a credit line to the material. If material is not included in the article’s Creative Commons licence and your intended use is not permitted by statutory regulation or exceeds the permitted use, you will need to obtain permission directly from the copyright holder. To view a copy of this licence, visit http:// creat iveco mmons. org/ licen ses/ by/4. 0/. The Creative Commons Public Domain Dedication waiver (http:// creat iveco mmons. org/ publi cdoma in/ zero/1. 0/) applies to the data made available in this article, unless otherwise stated in a credit line to the data. To the editor, We read the recently reported study by Drs MartínFernández et al. [1] with interest given the growing discussion over target oxygenations levels in critical care settings [2]. The authors report the result of a secondary analysis of a prospective cohort of 454 adult patients admitted to surgical ICU with a diagnosis of post-surgical sepsis or septic shock, requiring invasive mechanical ventilation (IMV). The authors sought to compare outcomes between groups stratified on the basis of the partial pressure of arterial oxygen (PaO2) at the time of baseline assessment and concluded that hyperoxemia (defined as a PaO2 > 100 mmHg on the day of sepsis onset and maintained throughout 48 h) was associated with shorter duration of IMV, prolonged survival time, and reduced odds of death at 90 days, when compared to a baseline paO2 of < 100 mmHg (“normoxemia”). We feel, however, that certain aspects of the study design and data analysis warrant greater clarification to facilitate drawing accurate conclusions. Given the observational nature of this analysis, great care must be given to accounting for confounders. When comparing the baseline demographics (Additional file 1: Table S1), significant differences were demonstrated, many of which do not appear to have been included in the final multivariate models, including the significantly higher rate of chronic lung disease (22.3% vs 12.5%, p = 0.005), respiratory sepsis (73% vs 33%, p < 0.001) and septic shock (84.0% vs 67.1%, p < 0.001) in the normoxemia group. Moreover, details regarding the differences in the proportion and severity of ARDS between groups are lacking. Based on the median PaO2/FiO2 ratios (157.64 vs 278 mmHg, p < 0.001), the data would suggest that most patients in the hyperoxia group had at most mild ARDS while those in the normoxia group had at least moderate ARDS (provided other diagnostic criteria were met). Conversely, chronic renal failure was included in multivariate models, despite no significant difference between the stratified groups (20% vs 21%, p = 0.66), while data on acute kidney injury, a more significant predictor of negative outcome in ICU than chronic kidney disease, was not presented. Collectively, these issues are crucial to informed interpretation of the results, given that an association between lung disease and the primary stratification (PaO2) was clearly demonstrated in the study, and chronic lung disease and ARDS are known to be a predictors of worse survival outcomes in ICU and post-surgery [3, 4]. Similar effects, specifically for time on ventilator, would be expected to be associated with respiratory sepsis and ARDS compared to other causes. We would suggest that clarification of the selection criteria for co-variates should be provided. Based on the data presented and the outcomes of interest, adjustment for chronic lung disease, respiratory sepsis, shock and ARDS severity would appear to be both statistically and clinically appropriate. Open Access


To the editor,
We read the recently reported study by Drs Martín-Fernández et al. [1] with interest given the growing discussion over target oxygenations levels in critical care settings [2]. The authors report the result of a secondary analysis of a prospective cohort of 454 adult patients admitted to surgical ICU with a diagnosis of post-surgical sepsis or septic shock, requiring invasive mechanical ventilation (IMV). The authors sought to compare outcomes between groups stratified on the basis of the partial pressure of arterial oxygen (PaO 2 ) at the time of baseline assessment and concluded that hyperoxemia (defined as a PaO 2 > 100 mmHg on the day of sepsis onset and maintained throughout 48 h) was associated with shorter duration of IMV, prolonged survival time, and reduced odds of death at 90 days, when compared to a baseline paO 2 of < 100 mmHg ("normoxemia"). We feel, however, that certain aspects of the study design and data analysis warrant greater clarification to facilitate drawing accurate conclusions.
Given the observational nature of this analysis, great care must be given to accounting for confounders. When comparing the baseline demographics (Additional file 1: Table S1), significant differences were demonstrated, many of which do not appear to have been included in the final multivariate models, including the significantly higher rate of chronic lung disease (22.3% vs 12.5%, p = 0.005), respiratory sepsis (73% vs 33%, p < 0.001) and septic shock (84.0% vs 67.1%, p < 0.001) in the normoxemia group. Moreover, details regarding the differences in the proportion and severity of ARDS between groups are lacking. Based on the median PaO 2 /FiO 2 ratios (157.64 vs 278 mmHg, p < 0.001), the data would suggest that most patients in the hyperoxia group had at most mild ARDS while those in the normoxia group had at least moderate ARDS (provided other diagnostic criteria were met). Conversely, chronic renal failure was included in multivariate models, despite no significant difference between the stratified groups (20% vs 21%, p = 0.66), while data on acute kidney injury, a more significant predictor of negative outcome in ICU than chronic kidney disease, was not presented.
Collectively, these issues are crucial to informed interpretation of the results, given that an association between lung disease and the primary stratification (PaO 2 ) was clearly demonstrated in the study, and chronic lung disease and ARDS are known to be a predictors of worse survival outcomes in ICU and post-surgery [3,4]. Similar effects, specifically for time on ventilator, would be expected to be associated with respiratory sepsis and ARDS compared to other causes. We would suggest that clarification of the selection criteria for co-variates should be provided. Based on the data presented and the outcomes of interest, adjustment for chronic lung disease, respiratory sepsis, shock and ARDS severity would appear to be both statistically and clinically appropriate.
*Correspondence: Alex.Franciosi@HLI.ubc.ca Furthermore, while patients with a PaO 2 < 100 mmHg were classified as 'normoxemic' in this study, this grouping combines severely hypoxemic individuals (with PaO 2 < 60 mmHg) with normoxemic/moderately hypoxemic individuals. The former represents a wholly different class of risk. Indeed, in the original Fig. 2 (plot of adjusted odds (aOR) of death versus PaO 2 ), most of the incresead mortality risk was associated with a PaO 2 < 60 mmHg, a clearly sub-optimal oxygenation status, and not one that has been entertained in the wider discussion over liberal vs conservative oxygen strategies. Though the authors performed sub-analyses excluding individuals with paO 2 < 60 mmHg, reporting results consistent with the main analyses, in Fig. 2 no definitive association between improved survival and higher oxygenation was seen above a PaO 2 of 60 mmHg, especially given the wide confidence intervals displayed as the PaO 2 passes to > 100 mmHg. Indeed, no difference in the aOR of death was seen at all between a PaO 2 of ≳ 60 and ≲ 175 mmHg. Again, whether clinically appropriate covariates were included in the multivariate sub-analyses should be clarified.
Summarily, the results appear to suggest that profound hypoxemia at the onset of sepsis post-surgery is a predictor of poorer outcomes, but how much of this this effect is accounted for by the significant baseline differences is unclear. By the same logic, the conclusion that baseline PaO 2 > 100 mmHg was "independently" associated with better outcomes is questionable.
Finally, it is important to point out that stratification based on PaO 2 formed the basis of this post-hoc analysis of an observational study, but to our understanding the same PaO 2 measurements were not the result of pre-specified oxygen titration strategies, randomized to achieve dichotomized target PaO 2 ranges. Consequently, though the authors state in the introduction that their study might help to "test the hypothesis that hyperoxemia would improve outcome compared to conservative oxygen therapy in patients with sepsis/septic shock" such a hypothesis cannot be tested by this study design. As such, the author's assertion that their findings "could have an important clinical relevance for reducing overall mortality in postoperative patients developing sepsis/ septic shock" should be interpreted with care.

Marta Martín-Fernández, Eduardo Tamayo and Jesús Villar (on behalf of all authors)
Dear Editor, We would like to thank to Dr. Franciosi and colleagues for their interest and comments about our article [1]. As they mentioned, in recent years, there has been a great interest on knowing the optimal levels of oxygenation in critically ill patients. Summary data from meta-analyses seem to indicate that hyperoxemia worsens outcome [5]. However, according to a recent systematic review with data from eight trials (4415 participants), the authors did not find differences in mortality (OR 0.95, 95% CI 0.74-1.22) between high or low oxygen targets in mechanically ventilated adults. However, the high heterogeneity and the overlapping target ranges limit its validity and clinical relevance, and calls for urgent further research to define optimal oxygen therapy targets [6]. There are controversial findings in patients with septic shock. For example, in the ICU-ROX trial, no differences were found when comparing conservative versus liberal oxygen therapy [7]. In addition, the use of hyperoxic therapy reduced the risk of surgical site infections in colorectal surgery [8], probably due to the bactericidal activity of neutrophils mediated by oxidative killing, a potent mechanism that depends on the production of superoxide radicals from molecular oxygen.
We sought to review our historical series of septic patients focusing on the PaO 2 values at the time of sepsis diagnosis and within the first 48 h after diagnosis. We observed that patients with PaO 2 > 100 mmHg had lower 90-day mortality (25.5% vs. 37.0%, p = 0.008). Also, the potential association between PaO 2 levels and risk of 90-day mortality in our study was further evaluated by using a multivariate logistic regression analysis. Using the variables in Table 1, a univariate regression analysis was performed for 90-day mortality. Variables showing a p value < 0.1 with no collinearity were included as adjustment variables in the multivariate analysis. Chronic cardiovascular disease, chronic respiratory disease, cancer, obesity, urgent surgery and platelet count showed a p value > 0.1 while bilirubin, creatinine, lactate, neutrophils and white blood cells showed collinearity with APACHE II score. C-reactive protein showed collinearity with procalcitonin. The variables considering "time function", such as mechanical ventilation, ICU and hospital stay, were considered not to be mixed with variables of admission day. Thus, Table 1 just compares patients with PaO 2 ≤ 100 mmHg versus PaO 2 > 100 mmHg.
Furthermore, our study only showed an association between mortality and PaO 2 ≤ 100 mmHg. We thought that this finding is clinically relevant and should be validated in a clinical trial fashion design, as stated in our paper.
Additional file 1. Baseline characteristics of patients.

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